Changes in rate of RNA synthesis and ribosomal gene number during oogenesis of Drosophila melanogaster.

A new method for separating Drosophila egg chambers into different developmental classes (Jacobs-Lorena and Crippa, 1977) made it possible to study changes in the rate of ribosomal RNA (rRNA), 5S RNA, and tRNA synthesis and the changes in ribosomal gene number during oogenesis. Synthesis of RNA was measured by [³H]uridine incorporation in vivo and subsequent analysis on sucrose gradients or gel electrophoresis. Specific radioactivity of nucleotide pools has also been determined. Ribosomal gene number has been measured by hybridization of egg chamber DNA to rRNA of high specific radioactivity. Our findings led us to conclude that in Drosophila melanogaster: (i) rRNA, 5S RNA, and tRNA are synthesized in all stages of oogenesis. (ii) In every stage, rRNA is the main RNA species synthesized. (iii) The rate of rRNA, 5S RNA, and tRNA synthesis increases greatly during oogenesis and is paralleled by a similar increase in ribosomal gene number resulting from the polyploidization of the nurse cell nuclei.     

Chromosome structure and DNA replication in nurse and follicle cells of Drosophila melanogaster

In the nurse cells of Drosophila, nuclear DNA is replicated many times without nuclear division. Nurse cells differ from salivary gland cells, another type of endoreplicated Drosophila cell, in that banded polytene chromosomes are not seen in large nurse cells. Cytophotometry of Feulgen stained nurse cell nuclei that have also been labeled with ³H-thymidine shows that the DNA contents between S-phases are not doublings of the diploid value. In situ hybridization of cloned probes for 28S+18S ribosomal RNA, 5S RNA, and histone genes, and for satellite, copia, and telomere sequences shows that satellite and histone sequences replicate only partially during nurse cell growth, while 5S sequences fully replicate. However, during the last nurse cell endoreplication cycle, all sequences including the previously under-replicated satellite sequences replicate fully. In situ hybridization experiments also demonstrate that the loci for the multiple copies of histone and 5S RNA genes are clustered into a small number of sites. In contrast, 28S+18S rRNA genes are dispersed. We discuss the implications of the observed distribution of sequences within nurse cell nuclei for interphase nuclear organization. — In the ovarian follicle cells, which undergo only two or three endoreplication cycles, satellite, histone and ribosomal DNA sequences are also found by in situ hybridization to be underrepresented; satellite sequences may not replicate beyond their level in 2C cells. Hence the pathways of endoreplication in three cell types, salivary gland, nurse, and follicle cells, share basic features of DNA replication, and differ primarily in the extent of association of the duplicated chromatids.     

Unintegrated ribosomal genes in diploid and polytene tissues of Drosophila melanogaster

We have examined DNA from polytene salivary glands and diploid brains and imaginal discs of male and female larvae having one or two nucleolus organizers. DNA having an estimated molecular weight of 5×10⁹ or greater was obtained by sucrose gradient sedimentation of gently prepared lysates. Hybridization of the gradient fractions with ³H-ribosomal RNA reveals that 42% of the ribosomal genes are found in DNA of lower molecular weight (approximately 3×10⁸ daltons) in the salivary glands of every genotype examined. In the brains and imaginai discs, by contrast, all of the ribosomal genes are found in the high molecular weight peak except in females with one nucleolus organizer where 42% are found in lower molecular weight DNA, as in the salivary gland. Thus unintegrated genes are not an exclusive feature of polytene tissue, but can occur in diploid tissue as well in at least one genotype.     

The location of 5S (ribosomal) RNA genes in Drosophila hydei

The location of the 5S ribosomal RNA cistrons in band 2-23B1,2 of the polytene (salivary gland) chromosomes of Drosophila hydei was indicated by in situ hybridization of tritiated low molecular weight RNA fractionated from total in vivo synthesized larval RNA or from in vitro synthesized salivary gland RNA and competition of the hybridization of this RNA by 5S RNA obtained from calf lens ribosomes. -- At the submicroscopic level, band 2-23B1,2 in salivary gland chromosomes shows a compact organization. The adjacent region, 23B2, is slightly puffed and displays typical RNP particles, some of which may be observed close to band 2-23B1,2.     

The differential regulation of the synthesis of ribosomal RNA, 5 S RNA, and 4 S RNA in the polytenic salivary gland cells of the blowfly, Calliphora erythrocephala

Third-instar larvae of the blowfly Calliphora erythrocephala were injected with [2-³H]adenosine, and its flow into the salivary gland ATP pool and each of several electrophoretically resolved salivary gland RNA species were quantitated. From these data, the individual in vivo rates of synthesis, accumulation, and processing of salivary gland ribosomal RNA (rRNA), 4 S RNA, and 5 S RNA have been measured at several different developmental stages. These results indicate that the synthesis of 5 S RNA and rRNA are coordinate, developmentally regulated, and independent of the synthesis of 4 S RNA. A nonribosomal, heterodisperse RNA component (hdRNA) was also identified. This species contributes to both the rapidly turning over pulse-labeled RNA and the accumulating pulse-labeled RNA populations. Indirect measurements suggest that the developmental pattern of regulation of this RNA species is also independent of 5 S RNA and rRNA synthesis. The rate of synthesis and accumulation of each of these RNA species either remained constant or declined during the first three-fourths of the instar, despite a six- to sevenfold increase in the content of cellular DNA.     

Differential replication of ribosomal gene repeats in polytene nuclei of Drosophila.

The genes coding for the 18S and 28S rRNAs in D. melanogaster were examined using Southern transfers of DNA from diploid or polytene tissue. A ribosomal gene repeat 12 kb in length is present in DNA from diploid tissue of males and is the major repeat on the Y chromosome. This repeat is present in low amounts on the X chromosome, which contains major repeats of 17 and 11.5 kb. In polytene nuclei of males, the 12 kb band is disproportionately replicated, and only a very low amount of the 11.5 kb repeat and no 17 kb repeat are detected. Polytene nuclei of females contain reduced amounts of the 17 kb repeat relative to the 11.5 kb repeat. This disproportionate replication of specific ribosomal gene repeats suggests that polytenization of the rDNA may involve an extrachromosomal mechanism. Evidence that genes from only one nucleolus organizer are replicated during polytenization in X/Y and X/X flies is discussed. A method for analyzing DNA from tissue of individual larvae was developed to test for population heterogeneity in ribosomal gene structure. Heterogeneity was observed in the ribosomal genes of three Ore R lines, four other D. melanogaster strains and between males and females of the same strain.     

Sequence replication and banding organization in the polytene chromosomes of Drosophila melanogaster

The relative proportions of cloned DNA fragments from all known hierarchies of sequence organization in polytene and diploid chromosomes were compared. It was found that unique sequences of varying sizes and chromosomal locations are equally replicated in salivary gland chromosomes. Sequences of euchromatic polydisperse gene families are also replicated proportionately in polytene and diploid tissues. Perhaps the most significant finding is that the histone gene repeats, despite their normal banding organization, are under-replicated in the polytene chromosome of Drosophila melanogaster. However, the clustered and well-banded 5S genes are most likely equally replicated. It is therefore concluded that differential sequence replication plays no apparent role in either the assembly or morphology of a band; and likewise, the assembly of polytenic DNA into band units is not affected by either the local abundancy or arrangement of middle repetitive sequences. The likelihood that the clustered arrangement is an important factor in the selection of sequences for under-replication is discussed.     

DNA replication in synchronized cultured mammalian cells : VI. The temporal replication of ribosomal cistrons in synchronized cell lines

The time of synthesis of ribosomal genes was studied in a haploid (Rana pipiens), and a pseudodiploid (Chinese hamster) cell line. R. pipiens cells were synchronized by amethopterin block. Chinese hamster cells were synchronized by isoleucine starvation followed by hydroxyurea treatment. DNA replicated during three or four selected intervals of the S period was separated from the remainder of the DNA by bromodeoxyuridine density labeling. Purified bromodeoxyuridine substituted DNA was annealed with radioactive-labeled 28S ribosomal RNA (rRNA) to determine when, during different intervals of S, the nuclear DNA homologous to rRNA was replicated. In the R. pipiens and Chinese hamster cell lines, the percent of nuclear DNA homologous to 28S rRNA is highest in the DNA replicated during the first half of the S period.     

Determination of the region of rDNA involved in polytenization in salivary glands of Drosophila hydei

During the formation of polytene chromosomes in salivary glands of Drosophila hydei, the genes for ribosomal RNA (rDNA) are underreplicated relative to the rest of the genome. We have measured the number of rRNA genes with and without intervening sequences (ivs+ and ivs- genes) in polytene chromosomes of different genotypes. In the group of genotypes having a large number of ivs- rRNA genes polytenization only occurs within the cluster of ivs- genes. In each of these genotypes rDNA polytenization reaches a constant level of 150 ivs- genes per two chromatid sets (2C); X/X constitutions having two nucleolus organizers (NOs) in the diploid set polytenize the same amount of rDNA as X/O constitutions. In the group of genotypes with small ivs- gene numbers, the rDNA region involved in polytenization is longer and has an average length of 1,700 kb per NO, which is constant in these genotypes. Polytenization of rDNA is extended into the cluster of ivs+ genes, in spite of the fact that these genes appear to be nonfunctional. The smaller the number of ivs- genes, the greater the number of ivs+ genes that are polytenized in the NO. In these genotypes, X/X females replicate twice as much rDNA as X/O males, suggesting that both NOs of the diploid set are polytenized. A comparison of the pattern of spacer length heterogeneity in hybrids between different stocks also demonstrates that both NOs are replicated during polytenization.     

Apoptosis of nurse cells at the late stages of oogenesis of Drosophila melanogaster

 In Drosophila a remarkable feature of oogenesis is the regression of the nurse cells after dumping their cytoplasmic contents into the oocyte. We have studied the nature of this process at the late stages of egg chamber development. In egg chambers DAPI staining shows highly condensed chromatin from stage 12 and TUNEL labelling shows DNA fragmentation up to stage 14. Gel electrophoresis of the end-labelled DNA, extracted from isolated egg chambers at the same stages of development, shows a ladder typical of apoptotic nuclei. This provides evidence that, during Drosophila oogenesis, the nurse cells undergo apoptosis. Apoptotic nuclei have also been detected in dumping-defective egg chambers, indicating that the cytoplasmic depletion of nurse cells is concurrent with but apparently not the cause of the process. Received: 12 December 1997 / Accepted: 6 January 1998     

Identification and cytogenetic localization of vitelline membrane messenger RNAs in Drosophila

During stages 9 and 10 of oogenesis in Drosophila the major proteins involved in vitelline membrane (VM) formation are synthesized and secreted by the somatic follicle cells surrounding the oocyte. To identify potential mRNAs involved in VM protein synthesis, newly synthesized poly(A)-containing RNA from egg chambers of different developmental stages was studied. Urea-agarose gel electrophoresis revealed two RNA bands in stage 10 egg chambers in the size range expected for those which encode the smaller VM proteins. These RNA bands, T₁ and T₂, are specifically enriched in stage 10 follicle cell preparations. In vitro translations in reticulocyte lysates in the absence and presence of microsomal membranes showed both RNA bands code for products that are synthesized in precursor forms which are processed to species that comigrate with VM proteins. T₂ directed the synthesis of processed species that comigrated with the 23- to 24-kDa and 17.5-kDa VM proteins (J. Fargnoli and G. L. Waring, 1982, Dev. Biol. 92, 306–314) while the T₁ translation product comigrated with the 14-kDa protein. To determine the cytogenetic location of the genes encoding T₁ and T₂ RNAs, radiolabeled T₁ and T₂ RNAs were hybridized in situ to salivary gland chromosomes. The results suggest that the structural genes coding for the small vitelline membrane proteins are localized at two sites on the second chromosome: 39DE and 42A.     

The organization of ribosomal RNA genes in the mitochondrial DNA of Tetrahymena pyriformis strain ST.

1. We have constructed a physical map of the mtDNA of Tetrahymena pyriformis strain ST using the restriction endonucleases EcoRI, PstI, SacI, HindIII and HhaI. 2. Hybridization of mitochondrial 21 S and 14 S ribosomal RNA to restriction fragments of strain ST mtDNA shows that this DNA contains two 21-S and only one 14-S ribosomal RNA genes. By S1 nuclease treatment of briefly renatured single-stranded DNA the terminal duplication-inversion previously detected in this DNA (Arnberg et al. (1975) Biochim. Biophys. Acta 383, 359--369) has been isolated and shown to contain both 21-S ribosomal RNA genes. 14 S ribosomal RNA hybridizes to a region in the central part of the DNA, about 8000 nucleotides or 20% of the total DNA length apart from the nearest 21 S ribosomal RNA gene. 3. We have confirmed this position of the three ribosomal RNA genes by electron microscopical analysis of DNA . RNA hybrid molecules and R-loop molecules. 4. Hybridization of 21 S ribosomal RNA with duplex mtDNA digested either with phage lambda-induced exonuclease or exonuclease III of Escherichia coli, shows that the 21-S ribosomal RNA genes are located on the 5'-ends of each DNA strand. Electron microscopy of denaturated mtDNA hybridized with a mixture of 14-S and 21-S ribosomal RNAs show that the 14 S ribosomal RNA gene has the same polarity as the nearest 21 S ribosomal RNA gene. 5. Tetrahymena mtDNA is (after Saccharomyces mtDNA) the second mtDNA in which the two ribosomal RNA cistrons are far apart and the first mtDNA in which one of the ribosomal RNA cistrons is duplicated.     

Chromatin condensation of ovarian nurse and follicle cells is regulated independently from DNA fragmentation during Drosophila late oogenesis

Programmed cell death constitutes a common fundamental incident occurring during oogenesis in a variety of different organisms. In Drosophila melanogaster, it plays a significant role in the maturation process of the egg chamber. In the present study, we have used an in vitro development system for studying the effects of inducers and inhibitors of programmed cell death during the late stages of oogenesis. Treatment of the developing egg chambers with two widely used inducers of cell death, etoposide and staurosporine, blocks further development and induces chromatin condensation but not DNA fragmentation in nurse and follicle cells, as revealed by propidium iodide staining and terminal transferase-mediated dUTP nick-end labeling assay. Moreover, incubation of the developing egg chambers with the caspase-3 inhibitor Z-DEVD-FMK significantly delays development, prevents DNA fragmentation, but does not affect chromatin condensation. The above results demonstrate, for the first time, that chromatin condensation in Drosophila ovarian nurse and follicle cells is a caspase-3-like independent process and is regulated independently from DNA fragmentation.     

Developmentally regulated RNA binding proteins during oogenesis in Xenopus laevis

During oogenesis, Xenopus oocytes synthesize and accumulate all types of RNA. In particular, they store poly(A+) RNA to such an extent that only about 5% is actually translated in the oocyte. Using a protein blotting and in vitro binding assay, we have identified proteins which are associated with poly(A+) RNA and perhaps other RNAs as well. Two groups of binding proteins were identified. The first group accumulates during oogenesis, generally is less than 50,000 molecular weight, and sediments in the 80 S and polysome regions of a gradient. These proteins most likely include ribosomal proteins. A second group of proteins is oocyte-specific, sediments less than 80 S as well 80 S and slightly heavier, generally has molecular weights greater than 50,000, and diminishes in amount as oogenesis progresses. In addition, these proteins are retained by oligo(dT)-cellulose when ribonucleoproteins are analyzed by chromatography and, when challenged with several different types of RNA in vitro, bind poly(A+) RNA preferentially. The possibility that some of these proteins might regulate the stability or translatability of mRNAs during oogenesis is discussed.